Alpheus tigrinus, Anker, 2024

Alpheus tigrinus sp. nov.

Figs. 18–23 View FIGURE 18 View FIGURE 19 View FIGURE 20 View FIGURE 21 View FIGURE 22 View FIGURE 23 , 24A–E View FIGURE 24

(+ Alpheus cf. tigrinus : Figs. 25A, B View FIGURE 25 ; Alpheus aff. tigrinus : Figs. 24F, G View FIGURE 24 , 25C–G View FIGURE 25 )

Alpheus djiboutensis View in CoL . — Luther 1958a: 175, figs. 1–3; Luther 1958b: 144; Holthuis 1958: 25, fig. 9; Debelius 2001: 152 (part.), 2 colour photographs [small photograph = A. tigrinus sp. nov.; large photograph = A. aff. tigrinus , see text] [not A. djiboutensis De Man, 1909 View in CoL ].

Alpheus djeddensis. View in CoL — Dehghani et al. 2019: 483, fig. 2C, D [not A. djeddensis Coutière, 1897 View in CoL ].

(?) Alpheus djeddensis View in CoL sensu lato. — Anker & De Grave 2016: 350, fig. 8 [not A. djeddensis Coutière, 1897 View in CoL , probably = A. aff. tigrinus , see text].

(?) Alpheus sp. cf. djiboutensis . — Anker 2000: 5, fig. 6 [not A. djiboutensis De Man, 1909 , = A. aff. tigrinus , see text].

(?) Alpheus sp. — Karplus & Thompson 2011: 591, fig. 4.4.10D [= A. aff. tigrinus , see text].

(?) Alpheus sp. A .— Senou et al. 2004: 300, colour photograph [probably = A. aff. tigrinus , see text].

(?) Alpheus sp. 3 .— Minemizu 2013: 102, colour photograph [= A. aff. tigrinus , see text].

(?) Alpheid shrimp. — Randall et al. 1998: 399, upper photograph [probably = A. aff. tigrinus , see text].

(?) Alpheid shrimp. — Randall 2005: 527, upper photograph [probably = A. aff. tigrinus , see text].

Type material. Holotype: male (cl 15.3 mm), FLMNH UF 37012 , Red Sea , Saudi Arabia, Farasan Islands, Zahrat Durakah (Zahirah), 16°50’09.2”N / 42°18’22.7”E, fringing reef / slope, depth 2–6 m, leg. A.Anker et al., 11.03.2013 (BDJRS-2702) GoogleMaps . Paratypes: 1 male (cl 12.1 mm), FLMNH UF 37014 , same collection data as for holotype (BDJRS-2704) GoogleMaps ; 1 male (cl 15.4 mm), FLMNH UF 37015 , same collection data as for holotype (BDJRS-2705) GoogleMaps ; 1 male (cl 11.4 mm), FLMNH UF 37001 , same collection data as for holotype (BDJRS-2688) GoogleMaps ; 1 male (cl 14.8 mm), FLMNH UF 37017 , same collection data as for holotype (BDJRS-2707) GoogleMaps ; 1 female (cl 13.7 mm, missing minor cheliped), FLMNH UF 48760 , Red Sea , Saudi Arabia, Farasan Islands , Zahrat Durakah ( Zahirah ), 16°50’06.0”N / 42°18’21.6”E, coral reef, 0–25 m, leg. D. Uyeno & M.L. Berumen, 28.10.2014 (BDJRS-6334); 1 ovig. female (cl 16.7 mm), FLMNH UF 36648 , Red Sea , Saudi Arabia, Farasan Islands, Tiger Head Island, 16.7910, 42.1987, karstic shore and fringing reef, depth 1–6 m, leg. A. Anker et al., 10.03.2013 (BDJRS-1767) GoogleMaps ; 1 male (cl 17.4 mm, missing major cheliped), FLMNH UF 36943 , same collection data as for previous paratype (BDJRS-2564) GoogleMaps ; 1 male (cl 13.0 mm), FLMNH UF 36957 , same collection data as for previous paratype, in burrow together with Cryptocentrus caeruleopunctatus (BDJRS-2585) GoogleMaps ; 1 male (cl 14.5 mm), FLMNH UF 36905 , Red Sea , Saudi Arabia, Farasan Islands , Abulad (Abu Lad), 16°47’51.7”N / 42°11’56.8”E, fringing reef / slope, depth 1–10 m, leg. A. Anker et al., 10.03.2013 (BDJRS-2435) GoogleMaps ; 1 male (cl 16.0 mm), FLMNH UF 36906 , same collection data as for previous paratype (BDJRS-2436) GoogleMaps .

Other material examined. 1 female (cl 9.4 mm), FLMNH UF 48648 , Red Sea, Saudi Arabia, Farasan Islands , North Ghorab Island, 17°06’32.4”N / 42°04’08.4”E, silty fringing reef, depth 5–7 m, leg. D. Uyeno GoogleMaps et al., 22.10.2014 (BDJRS-5831); 1 male (cl 9.7 mm), 1 ovig. female (cl 14.3 mm), RSRC, Red Sea, Saudi Arabia, Thuwal , KAUST, near King Abdullah Monument, 22°20’32.2”N / 39°05’03.1”E, sandflat with rubble and sparse seagrass near channel, depth 0.5–1 m, suction pump, in burrow, leg. A. Anker GoogleMaps , 24.09.22 (AA-22-239); 1 young female (cl indet., photographed and released), Red Sea, Saudi Arabia, Rabigh , northern end of flat desert peninsula 1 km south of coast guard station, 22°56’14.7”N / 38°50’55.1”E, hard bottom (rocky platform) with sandy patches, depth 0.3–1 m, suction pump, in burrow, leg. A. Anker GoogleMaps , 18.10.22 (AA-22-406); 1 female (cl 15.0 mm), RMNH. CRUS.D.14302, Red Sea, Sudan, Port Sudan, depth 1.5–3 m, in burrow in sand, leg. W. Luther.

Alpheus cf. tigrinus . 1 male (cl 14.3 mm, missing minor cheliped), FLMNH UF 71625 , United Arab Emirates, Abu Dhabi, Sir Bani Yas Island   GoogleMaps , sta. AD23-003, 24°22’04.8”N / 52°35’56.4”E, leg. A. Uehling et al., 16.06.2023 (ARAD-0104).

Alpheus aff. tigrinus . 1 young female (cl 5.8 mm), OUMNH. ZC.2014-11-038, Singapore, CMBS sta. YB188, St. John’s Island , DRTech northern lagoon, depth 0–0.5 m, sand patchily mixed with rubble, suction pump, leg. A. Anker, 05.06.2013 (SS-4529).

Diagnosis. Morphology largely as in A. djeddensis . Carapace strongly pitted, except for mid-dorsal portion, covered with short setae; anterolateral surface with several longer stiff setae ( Fig. 18A, B View FIGURE 18 ). Rostrum well developed, usually reaching well beyond mid-length of first article of antennular peduncle, sometimes almost reaching its distal margin; rostral carina distinct, blunt, raising above orbital hoods, extending well beyond base of orbital hoods, not reaching mid-length of carapace; orbital hoods unarmed, rounded; adrostral furrows shallow ( Figs. 18A, B View FIGURE 18 , 20B, C View FIGURE 20 , 23A, D View FIGURE 23 , 24C View FIGURE 24 ). Rostro-orbital region moderately protruding beyond anterolateral margin of carapace ( Figs. 18A, B View FIGURE 18 , 23A, D View FIGURE 23 ). Telson broad, about twice as long as wide at base, gently constricted near posterior third, tapering; dorsal surface faintly pitted, with two pairs of stout spiniform setae inserted at some distance from lateral margins; posterior margin broadly rounded, with row of slender spiniform setae between two pairs of more robust spiniform setae at each distolateral angle, mesial much longer than lateral ( Figs. 18C View FIGURE 18 , 23B View FIGURE 23 , 24D View FIGURE 24 ). Antennule with stylocerite swollen laterally, its tip falling well short of distal margin of first article of peduncle, ventromesial carina with subtriangular tooth; second article about 2.7 times as long as wide ( Figs. 18A, B, D View FIGURE 18 , 23A, D View FIGURE 23 , 24C View FIGURE 24 ). Antenna with distoventral margin of basicerite armed with acute tooth; scaphocerite with lateral margin faintly concave; distolateral tooth slightly or distinctly overreaching distal margin of blade ( Figs. 18A, B View FIGURE 18 , 23A, D View FIGURE 23 , 24C View FIGURE 24 ). Third maxilliped with penultimate article cup-shaped, widening distally, moderately convex ventrally, with some moderately elongate setae on distoventral margin ( Fig. 18E View FIGURE 18 ). Major cheliped of brevirostris type; merus stout, without tooth on distomesial margin, ventromesial margin with some spiniform setae; chela not elongate; palm about 1.7–1.9 times as long as wide, with deep transverse groove on dorsal margin, mesial surface faintly granulated; fingers about 0.6 length of palm; plunger of dactylus not bulging ( Figs. 19A–D, H View FIGURE 19 , 20D, E View FIGURE 20 , 23C, E View FIGURE 23 ). Minor cheliped distinctly shorter and weaker than major cheliped; merus without tooth on distomesial margin, ventromesial margin with some spiniform setae; chela not elongate; palm about 1.7–1.8 as long as wide, without grooves, mesial surface faintly granulated; fingers about 1.2–1.4 times as long as palm, somewhat gaping, typically not sexually dimorphic, with rows of balaeniceps setae on each side of dactylus and pollex in males and usually also in females, occasionally absent in females ( Figs. 19E–G, J View FIGURE 19 , 20F–H View FIGURE 20 , 23C View FIGURE 23 ). Second pereiopod with ratio of carpal subarticles equal to 3.0 / 2.5 / 1.0 / 1.0 / 1.5 ( Fig. 18F View FIGURE 18 ). Third pereiopod moderately slender; ischium armed with stout spiniform seta; merus about 4.5 times as long as maximal width, unarmed; propodus with seven or so spiniform setae along ventral margin and one pair of spiniform setae on distoventral angle; dactylus about 0.45 length of propodus, gradually curving distally, spatulate ( Fig. 18G–I View FIGURE 18 ). Fifth pereiopod ischium armed with spiniform seta ( Fig. 18J View FIGURE 18 ). Appendix masculina with stiff setae on apical part and along margin opposed to endopodal ramus ( Fig. 18L View FIGURE 18 ). Uropodal exopod with diaeresis almost sinuous, with broad lateral lobe; endopod with row of spiniform setae on distal margin ( Fig. 18M View FIGURE 18 ). Colour pattern diagnostic, as described below.

Colour pattern. Background colour whitish to pale yellow; carapace with several transverse (dorsally) and more oblique (laterally), red-brown bands; most bands with well-defined edges and without colourless areas within; anterolateral bands on each side of orbital hoods reddish brown; carapace flanks of larger individuals with large dark brown patch closer to posterior edge (absent in smaller individuals); rostrum whitish or yellowish; post-rostral area typically with large dark brown patch between eyes; pleon with conspicuous transverse banding consisting of one complete posterior band running across each pleonite and one incomplete anterior band occupying only anterodorsal section of each pleonite; saddle on first pleonite conspicuous, white with bright yellow markings; saddle on fourth pleonite less conspicuous, much smaller, yellowish; telson with anterior half largely white or white with yellowish tinge, often with two red-brown spots, and with posterior half dark brown, except white spots around spiniform setae; antennular peduncles yellow with orange-brown second article; stylocerite yellow with narrow orange-brown band along lateral edge; antennal carpocerite and scaphocerite mainly yellow, each with large orange-brown patch, that of scaphocerite occupying most of lateral surface near its mid-length; antennular and antennal flagella bright yellow, with orange tinge; chelipeds with pale blue or whitish background colour and dark purple-brown or brown-green patches on merus, most of carpus and mesial face of palm of chela, in latter case largely interconnecting; distodorsal surface of palm with small orange area near articulation with dactylus; pollex and dactylus with similar pattern as on palm on proximal half, calcified distal portion whitish with pale pink or orange tinge; lateral face of chelae with similar patches as on mesial face, sometimes with more intense blue tinge; second to fifth pereiopods largely blue with bright yellow articulations; uropods dominated by blue and yellow colour, with some dark brown or purple-red areas; eggs in ovigerous females green ( Figs. 21–23 View FIGURE 21 View FIGURE 22 View FIGURE 23 , 24A–E View FIGURE 24 ). See also Figs. 24F, G View FIGURE 24 , 25 View FIGURE 25 for colour patterns of A. cf. tigrinus and A. aff. tigrinus .

Etymology. The new species’ name ( tigrinus , related to or striped like a tiger) refers to its highly contrasting transverse banding; used as an adjective.

Common name. Tiger goby shrimp.

Type locality. Farasan Islands , Red Sea coast of Saudi Arabia .

Distribution. Western Indian Ocean: presently known with certainty only from the Red Sea ( Egypt, Israel, Saudi Arabia, Eritrea); highly likely also present in the Arabian-Persian Gulf ( Kuwait, UAE, Qatar, Iran; tentatively as A. cf. tigrinus , see below). Material or photographic records from other Indo-West Pacific localities ( Singapore, Indonesia, Taiwan, etc.) more likely refer to a different species (tentatively as A. aff. tigrinus , see below).

Ecology. Near-shore sandflats, reef flats and sandy patches between coral stands, from the intertidal to at least 15 m; typically associated with the goby Cryptocentrus lutheri ( Luther 1958a, as “ C. octofasciatus oder eine andere von uns noch nicht bestimmte Art”; Debelius 2001: 152, smaller photograph; unpublished photographs from Al Birk, Saudi Arabia [pers. obs.]; see also Fig. 25A, B View FIGURE 25 , as A. cf. tigrinus ); possible associations with C. caeruleopunctatus and C. cryptocentrus need confirmation.

Remarks. Alpheus tigrinus sp. nov. can be morphologically distinguished from A. djeddensis and A. shukran sp. nov. by the presence of several conspicuous, stiff, somewhat elongate setae on the anterolateral surface of the carapace, below each orbital hood ( Fig. 18A, B View FIGURE 18 ); these setae are absent in A. djeddensis and A. shukran sp. nov. ( Figs. 3A, B View FIGURE 3 , 4A, B View FIGURE 4 , 12A View FIGURE 12 ). Another morphological difference between these species lies in the proportions of the major and minor chelipeds, which are noticeably stouter in A. tigrinus sp. nov., with, for instance, the palm of the major chela being around 2.0 as long as wide (high) in A. tigrinus sp. nov. ( Fig. 19B, C, E, G, H View FIGURE 19 ) vs. 2.5 times or more as long as wide in A. djeddensis ( Figs. 2C–H View FIGURE 2 , 3F, G, J, K View FIGURE 3 ) and 2.3 times in A. shukran sp. nov. ( Fig. 12C–F View FIGURE 12 ). However, only adult specimens (with cl> 10 mm) with fully developed, non-regenerated chelipeds should be used in the comparison of the relative proportions of the chelipeds.

In both males and females of A. djeddensis and A. shukran sp. nov., the cheliped fingers possess low longitudinal crests furnished with dense rows of balaeniceps setae, including in relatively small specimens ( Figs. 1A View FIGURE 1 , 2G, H View FIGURE 2 , 3K, J View FIGURE 3 , 5C–E View FIGURE 5 , 7E View FIGURE 7 , 9E, F View FIGURE 9 , 12E, F View FIGURE 12 ). In A. tigrinus sp. nov., all fully grown males also have well-developed balaeniceps crests ( Figs. 19G, E, I View FIGURE 19 , 22B View FIGURE 22 , 23C View FIGURE 23 ), however, their development in females is less clear. The present material of A. tigrinus sp. nov., indicates that females of this species may not always have balaeniceps setae ( Figs. 19J View FIGURE 19 , 20F–H View FIGURE 20 , 21 View FIGURE 21 , 24A View FIGURE 24 ), although they seem to be present in all large females with normally developed, i.e., non-regenerated chelipeds, as in Holthuis’ (1958) female from Port Sudan ( Fig. 20F–H View FIGURE 20 ). Other characters, such as the length of the distolateral tooth relative to the distal margin of the blade, seem to be variable ( Figs. 18A View FIGURE 18 , 23A, D View FIGURE 23 , 24C View FIGURE 24 ), just like in A. djeddensis and A. shukran sp. nov. (see above and Figs. 1C View FIGURE 1 , 3A View FIGURE 3 , 4A View FIGURE 4 , 8A View FIGURE 8 , 9B View FIGURE 9 , 12A View FIGURE 12 , 13C, G View FIGURE 13 , 14C View FIGURE 14 ).

The major chelae of the female from Port Sudan and one of the males from the Farasan Islands are strongly curved mesially ( Figs. 20A View FIGURE 20 , 23C View FIGURE 23 ). A similar condition is found in the somewhat inadequately described A. cythereus Banner & Banner, 1966 , presently known only from the subsequently lost type specimen. However, A. cythereus differs from A. tigrinus sp. nov. and other species allied to A. djeddensis by the noticeably shorter second article of the antennular peduncle, the first carpal subarticle of the second pereiopod much shorter than the second, and the unarmed ischium of the third pereiopod (cf. Banner & Banner 1966: fig. 45A, G, H).

In life, A. tigrinus sp. nov. can be easily separated from A. djeddensis and A. shukran sp. nov. by several details of the colour pattern, such as the more contrasting banding dominated by dark red-brown colour (vs. with green-brown or blue tones in A. djeddensis and A. shukran sp. nov.); the carapace flanks with a large dark-brown area (vs. pale with some dark, obliquely descending bands in A. djeddensis and A. shukran sp. nov.); the bright yellow antennular and antennal flagella (vs. blue in A. djeddensis or pale greenish or yellowish in A. shukran sp. nov.); and the dorsal surface of the telson with whitish anterior half (typically with two brown-orange spots) and dark brown posterior half (vs. with a more mottled blue-brown-yellow patterns in A. djeddensis and A. shukran sp. nov.) (cf. Figs. 6–14 View FIGURE 6 View FIGURE 7 View FIGURE 8 View FIGURE 9 View FIGURE 10 View FIGURE 11 View FIGURE 12 View FIGURE 13 View FIGURE 14 , 21–23 View FIGURE 21 View FIGURE 22 View FIGURE 23 , 24A–E View FIGURE 24 ). In addition, A. tigrinus sp. nov. seems to prefer C. lutheri as partner goby, whereas A. djeddensis typically associates with C. caeruleopunctatus and possibly with C. cryptocentrus (see above). Furthermore, A. tigrinus sp. nov. can be separated from A. macellarius and A. cf. macellarius using the same criteria as for A. djeddensis (see above), including several striking differences in the colour pattern (cf. Figs. 15–17 View FIGURE 15 View FIGURE 16 View FIGURE 17 , 21–23 View FIGURE 21 View FIGURE 22 View FIGURE 23 , 24A–E View FIGURE 24 ).

The goby-associated snapping shrimps from the Arabian-Persian Gulf and the Iranian side of the Gulf of Oman, which have a colour pattern very similar to that A. tigrinus sp. nov. ( Fig. 25A–C View FIGURE 25 ; Dehghani et al. 2019: fig. 2C, as A. djeddensis ; not fig. 2D, see below) are possibly conspecific with those from the Red Sea. The only such specimen from the Arabian-Persian Gulf presently available to the author is an adult male from Abu Dhabi (FLMNH UF 71625) missing its minor cheliped ( Fig. 25A View FIGURE 25 ). This specimen agrees in all important features with the type specimens from the Red Sea, including the presence of elongate stiff setae on the anterolateral surface of the carapace, which appears to be the main diagnostic feature of A. tigrinus sp. nov. The geographical proximity of the Arabian-Persian Gulf to the Red Sea and common biogeographic patterns (e.g., Zajonz et al. 2022) would support the assumption that the Abu Dhabi specimen is conspecific with A. tigrinus sp. nov. In addition, photographic evidence suggests that in the Arabian-Persian Gulf shrimps associate with the same goby as A. tigrinus sp. nov. in the Red Sea, namely Cryptocentrus lutheri ( Fig. 25A, B View FIGURE 25 ). On the other hand, the colour pattern of the Abu Dhabi specimen is not as bright as that of the Red Sea specimens and it also differs from them by the absence of a dark patch on the carapace flanks and orange (rather than yellow or orange-yellow) antennal flagella (cf. Fig. 21 View FIGURE 21 , 22 View FIGURE 22 , 25A View FIGURE 25 ; see also Fig. 25B, C View FIGURE 25 ). Therefore, the incomplete Abu Dhabi male, which was collected only recently (in June 2023, i.e., after the original submission of the manuscript), is tentatively assigned to A. cf. tigrinus , awaiting its molecular comparison with the Red Sea material. It must be noted here that one of the photographs in Dehghani et al. (2019: fig. 2D) was used by these authors by mistake and without proper photographic credits. This photograph shows the paratype female of A. tigrinus sp. nov. from Farasan Islands on the Red Sea coast of Saudi Arabia ( Fig. 21 View FIGURE 21 ), and not “male pale morph (CL 9.8 mm)” of A. djeddensis from “Tis, Chabahar Bay” in Iran, as the legend claims (although a male specimen from this locality was listed under the material examined, see Dehghani et al. 2019: 483).

Outside of the western Indian Ocean, photo-vouchered material referrable to A. tigrinus sp. nov. or perhaps a closely related species is extremely scarce. The only specimen with a great similarity with A. tigrinus sp. nov. available for the present study is a young female (cl 5.8 mm) from Singapore ( Fig. 24F, G View FIGURE 24 ), which was already reported by Anker & De Grave (2016) under A. djeddensis sensu lato. The Singaporean female has essentially the same colour pattern as the young female from Rabigh, Saudi Arabia ( Fig. 24E View FIGURE 24 ), but lacks stiff elongate setae on the anterolateral region of the carapace (S. De Grave, pers. comm.). A thorough analysis of colour photographs taken in the “Coral Triangle” ( Malaysia, Indonesia, Philippines, Timor, Papua New Guinea) and adjacent areas of the western Pacific (southern Japan, Taiwan, eastern Australia), suggests the presence of at least one species closely related to A. tigrinus sp. nov., with a slightly different colour pattern. In this species, herein tentatively referred to as A. aff. tigrinus ( Fig. 25D–H View FIGURE 25 ), the antennular and antennal flagella are bright orange (rather than yellow as in A. tigrinus sp. nov. from the Red Sea, with A. cf. tigrinus from the Arabian-Persian Gulf being somewhat intermediate); the carapace flanks are dark violet with large circular or oval spots (not with a large dark patch as in A. tigrinus sp. nov.); and the distodorsal area of the palm has a conspicuous, bright orange spot near the base of the dactylus (which is present, but much smaller in A. tigrinus sp. nov.). Furthermore, A. aff. tigrinus is most often seen together with Cryptocentrus nigrocellatus (Yanagisawa) , C. albidorsus (Yanagisawa) or C. leucostictus (Günther) ( Fig. 25D, E, G, H View FIGURE 25 ; see also colour photographs in Randall et al. 1998: 399; Anker 2000: 5; Debelius 2001: 152, under A. djiboutensis , Bali; Randall 2005: 527; Kuiter & Debelius 2019: 152). The afore-mentioned young female from Singapore ( Fig. 24F, G View FIGURE 24 ) is tentatively assigned to A. aff. tigrinus , although its colour pattern is clearly not fully developed.

In summary, based on presently available, largely photographic evidence, the two most likely taxonomic / biogeographic scenarios are: (1) A. tigrinus sp. nov. is endemic to the Red Sea and is replaced in the remaining parts of the Indian Ocean (including the Arabian-Persian Gulf), South-East Asia and western Pacific by one or two closely related species ( A. cf. tigrinus , A. aff. tigrinus ); and (2) A. tigrinus sp. nov. is restricted to the western Indian Ocean, extending from the Red Sea to the Arabian-Persian Gulf (including material herein identified as A. cf. tigrinus ), and is represented by at least one closely related species ( A. aff. tigrinus ) in South-East Asia and western Pacific). The more numerous similarities of the colour patterns between the shrimps from the Red Sea ( A. tigrinus sp. nov.) and those from the Arabian-Persian Gulf ( A. cf. tigrinus ), combined with the presence of at least one diagnostic feature of A. tigrinus sp. nov. in the Abu Dhabi specimen (see above), and analogous biogeographic patterns observed in numerous other taxa, including its preferred partner goby, Cryptocentrus lutheri ( Eagderi et al. 2019) , would favour the second scenario. The third scenario, i.e., A. tigrinus sp. nov. having a wide Indo-West Pacific distribution, ranging from the Red Sea to Japan and Indonesia, and perhaps cooccurring with a closely related species in the “Coral Triangle”, is less likely, but cannot be totally excluded at this stage. Any of these hypotheses can be tested only after sequencing material of A. cf. tigrinus from the Arabian-Persian Gulf and collecting, examining and sequencing material of A. aff. tigrinus and other closely related forms from the “Coral Triangle” (see also below).